Identifying conversion efficiency as a key mechanism underlying food webs adaptive evolution: a step forward, or backward?

Body size or mass is one of the main factors underlying food webs structure. A large number of evolutionary models have shown that indeed, the adaptive evolution of body size (or mass) can give rise to hierarchically organised trophic levels with complex between and within trophic interactions. Howe...

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Veröffentlicht in:	Oikos 2021-06, Vol.130 (6), p.904-930
Hauptverfasser:	Fritsch, Coralie, Billiard, Sylvain, Champagnat, Nicolas
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Sprache:	eng
Schlagworte:	adaptive dynamics Biomass biomass conversion efficiency Body size community ecology Ecologists Ecology ecosystem Efficiency energy conversion efficiency Environmental Sciences & Ecology Evolution Evolution & development Food Food chains Food webs food webs models Life Sciences & Biomedicine networks Predators Prey reproduction efficiency Robustness Science & Technology trophic interactions Trophic levels Trophic relationships
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creator	Fritsch, Coralie Billiard, Sylvain Champagnat, Nicolas
description	Body size or mass is one of the main factors underlying food webs structure. A large number of evolutionary models have shown that indeed, the adaptive evolution of body size (or mass) can give rise to hierarchically organised trophic levels with complex between and within trophic interactions. However, these models generally make strong arbitrary assumptions on how traits evolve, casting doubts on their robustness. In particular, biomass conversion efficiency is always considered independent of the predator and prey size, which contradicts with the literature. In this paper, we propose a general model encompassing most previous models which allows to show that relaxing arbitrary assumptions gives rise to unrealistic food webs. We then show that considering biomass conversion efficiency dependent on species size is certainly key for food webs adaptive evolution because realistic food webs can evolve, making obsolete the need of arbitrary constraints on traits' evolution. We finally conclude that, on the one hand, ecologists should pay attention to how biomass flows into food webs in models. On the other hand, we question more generally the robustness of evolutionary models for the study of food webs.
doi_str_mv	10.1111/oik.07421
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A large number of evolutionary models have shown that indeed, the adaptive evolution of body size (or mass) can give rise to hierarchically organised trophic levels with complex between and within trophic interactions. However, these models generally make strong arbitrary assumptions on how traits evolve, casting doubts on their robustness. In particular, biomass conversion efficiency is always considered independent of the predator and prey size, which contradicts with the literature. In this paper, we propose a general model encompassing most previous models which allows to show that relaxing arbitrary assumptions gives rise to unrealistic food webs. We then show that considering biomass conversion efficiency dependent on species size is certainly key for food webs adaptive evolution because realistic food webs can evolve, making obsolete the need of arbitrary constraints on traits' evolution. 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subjects	adaptive dynamics Biomass biomass conversion efficiency Body size community ecology Ecologists Ecology ecosystem Efficiency energy conversion efficiency Environmental Sciences & Ecology Evolution Evolution & development Food Food chains Food webs food webs models Life Sciences & Biomedicine networks Predators Prey reproduction efficiency Robustness Science & Technology trophic interactions Trophic levels Trophic relationships
title	Identifying conversion efficiency as a key mechanism underlying food webs adaptive evolution: a step forward, or backward?
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